Method and System for Monitoring and Controlling a Glass Container Forming Process

ABSTRACT

The present invention relates to a method and system for monitoring and controlling a glass container forming process. The radiation emitted by each hot glass container is measured with measurement unit immediately after the forming machine. The described method normalizes the measurement from glass container to glass container and thereby removes the effects of overall temperature variations between glass containers, changing ambient conditions, and other variations affecting the measurements, which provides a unique quality reference for each glass container. By reviewing this reference for each produced glass container, the quality of the produced containers can be improved

CROSS REFERENCE TO RELATED APPLICATIONS

This patent application claims priority benefit under 35 U.S.C. §119(a)from European Patent Application No. EP 09075545.5 filed in the EuropeanPatent Office on Dec. 10, 2009, the entirety of which patent applicationis hereby incorporated herein by reference.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates generally to a method and system formonitoring and controlling a glass container forming process.

The present invention relates to a method and system for monitoring andcontrolling a glass container forming process. The forming process isaccomplished by a forming machine which may contain multiple independentsections, each section consisting of at least one forming station. Themethod comprises the steps of measuring radiation emitted by each hotglass container immediately after the forming machine. Based on thesemeasurements, information and control signals may be generated to adjustthe glass container forming process in order to improve the quality ofthe glass containers and by doing so reduce the number of bad glasscontainers produced.

A system of this type is disclosed in the European Patent EP 1525469 B1,to Dalstra, which describes a system for analyzing and monitoring aproduction process for glass products. The system is sensitive toradiation in the near infrared (“NIR”) region solely and it measures theNIR radiation of hot glass products, determines the average radiationintensity for at least two measurement regions, compares this averageintensity with a reference value, compares deviations between themeasurement regions, and, based on this comparison, when necessarygenerates an error signal. In addition, a cooling curve is calculatedand used as a reference to compensate for the difference in the amountof radiation of glass products due to different cooling times.

However, the system may generate error signals even when there is achange in the amount of radiation which is not brought about due to achange in the forming process, but is due instead to changes in thevarious conditions and parameters, such as, among others, the ambienttemperature, ambient humidity, production speed, cooling airtemperature, cooling air humidity, glass material composition, camerasettings, smoke and dirt in the air, pollution of the optics, andcontainer weight.

These conditions and parameters can drastically alter the measuredradiation intensities depending on, for example, whether operating atday or night, different seasons, the production location, and/or theforming machine.

Consequently, an operator should always be present to monitor themeasurement results and the generated error signals carefully, to checkthe conditions and parameters, and to adjust reference values in orderto compensate for continuously changing conditions and parameters. Froma practical point of view this is a very undesirable requirement, sincelabor costs are high and the forming process occurs in an extremely hotand noisy environment where labor conditions are quite unfavorable.

Another disadvantage of the system is that when starting the productionof a glass container which has been produced earlier, the abovementioned conditions and parameters may have been changed, in which casethe reference values and/or cooling curves used for the previousproduction may not be useful for the current production. In such a case,each time a new reference and/or a cooling curve is required, which willlengthen the start up time and is therefore not desirable.

It would be desirable to provide a method for monitoring and controllinga glass container forming process which is independent of the abovementioned conditions and parameters and with which it is possible toproduce glass containers with a high and constant quality.

It would also be desirable to generate a unique reference which servesas a quality reference for the type of container produced, in order toproduce glass containers at each forming station with the same qualitydepicted by this reference and to decrease the time necessary to startup the forming process. This unique reference may be stored and used tomonitor and control the same forming machine or another forming machineproducing the same particular glass container type at a differentlocation.

It would also be beneficial to eliminate the requirement of having anoperator monitoring the process constantly by instead controlling theforming machine automatically.

SUMMARY OF THE INVENTION

To achieve the above mentioned objects, the present invention relates toa method for monitoring and controlling a glass container formingprocess. The method measures infrared radiation emitted by hot glasscontainers immediately after the forming machine with a camera sensitiveto the radiation emitted by the hot glass containers. The glasscontainer image generated by the camera is arranged in a finite numberof image lines, each image line having a finite number of pixels, andperforms the following steps for each glass container measured from eachforming station:

a. determining a total radiation measurement for each glass container bysumming the digital values of all of the pixels in all of the imagelines for such glass container;b. determining a line radiation measurement for each image line for eachglass container by summing the digital values of all of the pixels insuch image line for such glass container; andc. determining a measurement-ratio curve for each glass container bydividing the line radiation measurements for each image line of suchglass container by the total radiation measurement for such glasscontainer.

The above mentioned problem of changing conditions and parameters isthereby compensated for by dividing the line radiation measurements bythe total radiation measurement. This can be explained as follows. When,for example, the radiation of a hot glass container is partly absorbedby some smoke in the air, the line radiation measurement for the glasscontainer get lower and the total measurement for the glass containergets lower. However, by dividing the line radiation measurements for theglass container by the total radiation measurement for the glasscontainer, the line radiation measurements are in effect normalized tocompensate for differences in total radiation measurement from glasscontainer to glass container (the measurement-ratio curve is thus anormalized curve that will not be affected by differences in totalradiation measurement from glass container to glass container).Obviously, this would not have been the case when, as in the prior art,absolute values of the radiation measurements for the glass containersare used without any normalizing of these values. (It should be notedthat the measurement-ration curve is actually a dimensionless curverather than being a dimensioned value.)

Glass containers originating from forming stations close to themeasurement unit when compared to glass containers from forming stationsfurther away from the measurement unit travel a shorter distance to themeasurement unit which takes less time, and thus cool down less andconsequently will have a higher temperature (and a correspondinglyhigher total radiation). In the prior art, a cooling curve was used tocompensate for such different cooling times. However, this cooling curveis based upon absolute measured values, and was therefore sensitive tochanges in above-mentioned conditions and parameters. According to thepresent invention, the measurement-ratio curve of the hot glasscontainers compensates for and normalizes the temperature of the glasscontainer. When a glass container from a forming station located furtheraway (which thus has a lower temperature) has the same glassdistribution as a glass container from a forming station closer to themeasurement unit (which thus has a higher temperature), themeasurement-ratio curves from both glass containers will be the sameinstead of being markedly different as they would have been in prior artteachings.

The measurement-ratio curve of a hot glass container can further becompared with a reference curve. The reference curve is unique for eachparticular glass container type, and thus serves as a quality measurefor each particular glass container type. In order to acquire thisunique reference curve, a preferred embodiment of method may perform thefollowing additional step:

d. determining a reference curve based upon a plurality of themeasurement-ratio curves over a predetermined number of hot glasscontainers.

Averaging the measurement-ratio curves over a number of hot glasscontainers may include summing the measurement-ratio curves of a numberof glass containers and dividing this sum by the number of glasscontainers. The measurement-ratio curves of the glass containers may beaveraged over a period of time, from one or more selected stations, overa number of production cycles, or over just one production cycle.

One may obtain various reference curves with different forming machinesettings, from which the one having the best performance, producing thebest quality of glass containers, may be selected. This reference curvecan be saved in order to be used when producing the same container typeat a later time, either on the same forming machine or on a differentforming machine. It can also be used to analyze and compare the currentproduction performance with a past production. If desired, the referencecurve can be continuously updated which may result in an even betterquality being achieved for the same container.

Another preferred embodiment of method according to the presentinvention comprises the following step:

e. determining a relative difference curve for each hot glass containerby subtracting the reference curve from the measurement-ratio curve ofsuch hot glass container and dividing the result by the reference curve.

The relative difference curve easily shows how much and where themeasurement-ratio curve of a glass container deviates from the referencecurve. The relative difference curve can be displayed for each formingstation in order to show the quality of the glass containers produced atthe forming station. When the quality of a produced glass container ishigh, the relative difference curve will be close to zero. When therelative difference curves of all containers from all stations are closeto zero, the quality of all containers produced by the forming machinewill be high and substantially equal.

Another preferred embodiment of method according to the presentinvention comprises the following steps:

f. comparing the relative difference curve with a predeterminedtolerance curve; andg. generating an alarm signal if the relative difference curve exceedsthe tolerance curve in at least one point.

By comparing the relative difference curve with a tolerance curve andgenerating an alarm signal if the difference exceeds the tolerancecurve, one can easily determine whether the quality of glass containersproduced by a forming station is acceptable or if it has degraded tosuch a degree that the container is of an inferior quality and thereforeunacceptable.

The tolerance curve may be constant, tolerating the same amount ofdeviation for every location on said container. However, the values ofthe tolerance curve may also be dependant on the location on saidcontainer. By doing so, one is for instance able to allow less deviationfrom the reference curve for one or more areas of the container wherethe tolerances (e.g., the tolerance of the glass thickness) arecritical. Furthermore, the tolerance values may be positive as well asnegative.

The control unit controls the forming process of each forming station bya number of process parameters. In order to control the forming processautomatically, another preferred embodiment of method according to thepresent invention comprises the following step:

h. sending the relative difference curve of each hot glass container tothe control unit to automatically control the forming process.

By sending the relative difference curves of glass containers from eachforming station to the control unit, the adjustment of the process maybe performed automatically and shortly after the detection of a changeor an error in the forming process. The adjustment will occur in such amanner that the relative difference curves substantially decreases tozero.

The measurement may be carried out at any wavelength at which a hotglass container emits radiation. Nevertheless, since radiation atwavelengths smaller than 3.0 microns from container glass is indicativeof both the glass temperature and the glass thickness, a more accuratemeasurement may be obtained at wavelengths smaller than 3.0 microns,especially when analyzing relatively thicker glass containers.Therefore, a preferred embodiment method according to the presentinvention is that said measurement occurs for wavelengths of between 0.7and 3.0 microns.

The present invention also relates to an analytical system formonitoring and controlling a glass container forming process. The systemcomprises at least one measurement unit to measure radiation emitted byeach hot glass container immediately after the forming machine. Themeasurement unit may comprise a line-scan or area camera sensitive tothe radiation emitted by the hot glass containers. The glass containerimage generated by the camera is arranged in a finite number of imagelines, with each image line having a finite number of pixels. Theprocessor unit provides calculations, comparisons, and communicationswith other units, wherein the processor unit is further programmed tocarry out the following steps:

a. determining a total radiation measurement for each glass container bysumming the digital values of all the pixels in all the image lines forsuch glass container;b. determining a line radiation measurement for each image line for eachglass container by summing the digital values of all the pixels in suchimage line for such glass container; andc. determining a measurement-ratio curve for each glass container bydividing the line radiation measurement for each image line of suchglass container by the total radiation measurement for such glasscontainer.

The processor unit is programmed such that it performs above mentionedoperation in order to make the measured values of radiation independentnot only of changes in parameters and conditions of the environment,process, and measuring equipment, but also independent of the formingstation where a hot glass container originates from.

A further preferred embodiment of the analytical system according to thepresent invention is that the processor unit is further programmed tocarry out the following step:

d. determining a reference curve by averaging the measurement-ratiocurves over a predetermined number of the hot glass containersoriginating from all or a selected number of forming stations.

By summing the measurement-ratio curves of a number of hot glasscontainers and dividing the sum by the number of containers, an averagemeasurement-ratio curve is acquired which is unique for a particulartype of glass container. The average measurement-ratio curve may serveas a reference for the quality of glass containers of that particulartype. It can also be utilized for another forming machine at a differentlocation when producing the same type of glass container with the samequality requirements.

Another preferred embodiment of analytical system according to thepresent invention is that the processor unit is further programmed tocarry out the following step:

e. determining a relative difference curve for each hot glass containerby subtracting the reference curve from the measurement-ratio curve ofeach hot glass container and dividing the result by the reference curve.

By determining the relative difference curve, the quality of a hot glasscontainer may be analyzed and the possible cause of a deficiency in theforming process may be indicated. By doing this, one can easily see howmuch and where the measurement-ratio curve of a hot glass containerdeviates from the reference curve. The relative difference curve can bedisplayed for each forming station in order to show the quality of theproduced glass containers and to show the performance of the formingprocess. When the quality of a produced glass container is high, therelative difference curve will be zero or negligibly small.

Another preferred embodiment of analytical system according to thepresent invention is that the processor unit is further programmed tocarry out the following step:

f. comparing the relative difference curve of each hot glass containerwith a predetermined tolerance curve;g. generating an alarm signal if the relative difference curve exceedsthe tolerance curve in at least one point.

By doing this, it can easily be determined whether the quality of theproduced glass containers at a forming station is acceptable or not. Thealarm signal may be used, for instance, to reject glass containers whichhave an unacceptable quality. The tolerance curve may be constant or itmay be variable dependant on the location on the glass container.

Still another preferred embodiment of analytical system according to thepresent invention is that the processor unit is further programmed tocarry out the following step:

h. sending the relative difference curve of each hot glass container tothe forming control unit to automatically control the forming process.

The processor unit sends the relative difference curve of each glasscontainer to the forming control unit, and the forming control unit,when necessary, adjusts one or more process parameters. This way, anautomatic adjustment of process parameters is feasible shortly after thedetection of an error or any detectable deficiency.

The measurement unit may be sensitive to any wavelength at which a hotglass container emits radiation. Nevertheless, since radiation atwavelengths smaller than 3.0 microns from container glass is indicativeof both the glass temperature and the glass thickness, a more accuratemeasurement may be obtained at wavelengths smaller than 3.0 microns,especially when analyzing relatively thicker glass containers.Therefore, a preferred embodiment of analytical system according to thepresent invention is that the measurement unit is sensitive towavelengths of between 0.7 and 3.0 microns. More specifically, themeasurement unit uses a Short Wave Infrared (“SWIR”) camera, for examplea 512 or 1024 pixels line-scan or area SWIR camera.

DESCRIPTION OF THE DRAWINGS

These and other advantages of the present invention are best understoodwith reference to the drawings, in which:

FIG. 1 shows a schematic view of a forming machine and an embodiment ofthe analytical system;

FIG. 2 shows an image of a glass container;

FIG. 3 shows the line radiation measurements for the glass containershown in FIG. 2;

FIG. 4 shows a measurement-ratio curve for the glass container shown inFIG. 2;

FIG. 5 shows a reference curve for the glass container shown in FIG. 2;

FIG. 6 shows a reference curve together with the measurement-ratio curvefor the glass container shown in FIG. 2; and

FIG. 7 shows a relative difference curve for the glass container shownin FIG. 2.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENT

FIG. 1 shows an embodiment of the system where the glass containerforming machine 20 contains six independent sections S1, S2, . . . S6,each of which contains two forming stations 22 and 24. In one productioncycle, the forming machine 20 produces twelve glass containers 30. Twomolten glass gobs 32 and 34 are formed at the same moment by the feederunit 36 and are loaded into the so-called blank molds 22 and 24. Eachsection S1, S2, . . . S6 of the forming machine 20 in this embodimentcontains two blank molds and 24 in which pre-containers or parisons areformed by pressing or blowing depending on the process type (press-blowor blow-blow). The formed parisons are transferred to the so-called blowmolds 26 and 28 where the parisons are blown into the final shape of theglass containers 30. The mechanisms of the forming machine 20 and thefeeder unit 36 are controlled by the control unit 38 through lines 52and 54, respectively. The glass containers 30 are transported by aconveyor belt 50 through a measurement unit 42 which takes images of thehot glass containers 30 and sends these images to a processor unit 44through a line 46. Although in this embodiment one measurement unit 42is used, the number of measurement units 42 may be increased dependingon the circumstances and the accuracy to be achieved. However, even withone measurement unit, the achieved accuracy is fairly high.

The measurement unit 42, an area camera in this embodiment, ispreferably sensitive to Short Wave Infrared (“SWIR”) radiation. Theimage taken by the camera of the hot glass container 30 shown in FIG. 2may, for example, contain 512 image-lines, with each image-line forexample containing 200 pixels.

The processor unit 44 determines for each glass container 30 the totalradiation measurement by summing the digital values of all the pixels inthe glass container image. The total radiation measurement of the glasscontainer shown in FIG. 2 has a value of 553. Next, the processor unit44 determines the line radiation measurements by summing for eachimage-line the digital values of all 200 pixels. The line radiationmeasurements belonging to the glass container image of FIG. 2 are shownin FIG. 3. Next, the processor unit 44, determines the measurement-ratiocurve by dividing the line radiation measurements by the total radiationmeasurement, as shown hereunder:

I _(tot,s) =ΣI _(x,y,s)(x=1,2, . . . 200,y=1,2, . . . ,512)

I _(y,s) =ΣI _(x,y,s)(x=1,2, . . . 200)

I _(ratio,y,s)=(I _(y,s) /I _(tot,s))*100%

Where:

-   -   I_(tot,s)=the total radiation measurement value of a glass        container image, originating from station s;    -   I_(x,y,s)=the digital value of pixel x, y of the glass container        image, originating from station s with y representing an        image-line containing 200 x pixels, x=1 . . . 200, y=1 . . .        512, s=1 . . . 12;    -   I_(y,s)=the line radiation measurement value for image-line (y)        of a glass container image, originating from station s; and    -   I_(ratio,y,s)=the measurement-ratio value for image-line y of a        glass container image, originating from station s.

The measurement-ratio values are expressed in percentages for clarity.The measurement-ratio curve depicted in FIG. 4 belongs to the glasscontainer shown in FIG. 2. The order in which these steps occur can bevaried as long as the same results are achieved. One can easily seethat, for example, an attenuation  of the radiation received from theglass container 30 caused by an ambient parameter (for example smoke inthe air) has no influence on the measurement-ratio curve:

I _(ratio,y,s)=(αI _(y,s) /αI _(tot,s))*100%=(I _(y,s) /I _(tot,s))*100%

Next, the processor unit 44 determines a reference curve by averagingmeasurement-ratio curves from a number of glass containers 30 from allor certain selected forming stations. This reference curve is unique forthe glass container type produced.

The values of the reference curve are derived as illustrated below:

$I_{{reference}\;,y} = {\left( {\sum\limits_{k = 1}^{N}\; I_{{ratio},y,k}} \right)/N}$

Where:

-   -   I_(reference,y)=the reference curve value for line (y); and    -   N=the number of glass containers 30 taken into account.

The reference curve may be stored and used later to decrease the timenecessary to start up the production of the particular glass container30 on the same or on another forming machine. The reference curvebelonging to the glass container type in this example is shown in FIG.5. In FIG. 6, the reference curve is shown together with themeasurement-ratio curve of FIG. 4.

The processor unit 44 next determines the relative difference curve bysubtracting the reference curve from the measurement-ratio curve anddividing the difference by the reference curve. This is illustratedhereunder:

ΔI _(s,y)=((I _(ratio,s) −I _(reference,y))/I _(reference,y))*100%

Where:

-   -   ΔI_(s,y)=the relative difference value at line y of a glass        container image originating from the station s.

The relative difference curve shows how much and where themeasurement-ratio curve of a glass container deviates from the referencecurve. The processor unit 44 may display on a connected monitor (notshown) for each forming station the relative difference curve in orderto show the quality of the glass containers produced at the formingstation. In FIG. 7, the relative difference curve is shown for the glasscontainer of FIG. 2 with the corresponding measurement-ratio curve shownin FIG. 4.

In this specific example the relative difference curve in FIG. 7 shows apositive deviation in the upper part of the glass container and anegative deviation in the lower part of the glass container, indicatingtoo much glass in the upper part of the glass container and too littleglass in the lower part of the glass container. The relative differencecurve will be close to zero at every point for high quality glasscontainers.

Subsequently, the processor unit (44) compares the relative differencecurve with predetermined tolerance curves and generates an alarm signalif a relative difference value exceeds the corresponding tolerancevalue. This is illustrated hereunder:

Alarm if:

ΔI _(s,y) <I _(T−y) or ΔI _(s,y) >I _(T+,y)

Where:

-   -   I_(T−,y)=the negative tolerance value for line y; and    -   I_(T+,y)=the positive tolerance value for line y.

The alarm signal may, for example, be used in order to reject glasscontainers which have an unacceptable quality on line 56 in FIG. 1. InFIG. 7 the negative tolerance values are set at −30% and the positivetolerance values are set at +30%. In FIG. 7 an alarm signal is generatedbecause the relative difference values for line 300 through line 380exceed the positive tolerance values.

In order to adjust the forming process automatically, the processor unit44 may send the relative difference curve from each forming station tothe control unit 38 over line 48. The control unit 38 adjusts theappropriate process parameters until the relative difference curve foreach forming station is close to zero. This is then achieved without theneed to have an operator monitoring the process continuously.

The processor unit 44 is synchronized with the forming machine 20 andwith conveyor belt 50 in such a way that processor unit 44 knows fromwhich forming station each glass container 30 originates.

The embodiment described above is intended solely to serve as anexample, and in no way is intended to restrict the invention. A personskilled in the art given knowledge of this invention will rapidly beable to accomplish other embodiments. Therefore, any variation on thetheme and methodology of accomplishing the same that are not describedherein would be considered under the scope of the present invention.

Although the foregoing description of the present invention has beenshown and described with reference to particular embodiments andapplications thereof, it has been presented for purposes of illustrationand description and is not intended to be exhaustive or to limit theinvention to the particular embodiments and applications disclosed. Itwill be apparent to those having ordinary skill in the art that a numberof changes, modifications, variations, or alterations to the inventionas described herein may be made, none of which depart from the spirit orscope of the present invention. The particular embodiments andapplications were chosen and described to provide the best illustrationof the principles of the invention and its practical application tothereby enable one of ordinary skill in the art to utilize the inventionin various embodiments and with various modifications as are suited tothe particular use contemplated. All such changes, modifications,variations, and alterations should therefore be seen as being within thescope of the present invention as determined by the appended claims wheninterpreted in accordance with the breadth to which they are fairly,legally, and equitably entitled.

1. A method for monitoring a glass container forming process wherein theforming process is accomplished by a forming machine which containsmultiple independent sections each having at least one forming stationat which glass containers are formed, comprising the steps ofdetermining digital values proportional to the radiation emitted by hotglass containers immediately after the forming machine with ameasurement unit sensitive to the radiation emitted by the hot glasscontainers, wherein the measurement unit generates a digital image ofeach hot glass container which is arranged in a finite number of imagelines, each image line having a finite number of pixels, each pixelhaving a digital value, characterized in that the method furthercomprises the following steps for each glass container measured fromeach forming station: a. determining a total radiation measurement foreach glass container by summing the digital values of all of the pixelsin all of the image lines for such glass container; b. determining aline radiation measurement for each image line for each glass containerby summing the digital values of all of the pixels in such image linefor such glass container; and c. determining a measurement-ratio curvefor each glass container by dividing the line radiation measurements foreach image line of such glass container by the total radiationmeasurement for such glass container.
 2. A method according to claim 1,wherein the method further comprises: d. determining a reference curvebased upon a plurality of the measurement-ratio curves over apredetermined number of the glass containers.
 3. A method according toclaim 2, wherein the method further comprises: e. determining a relativedifference curve for each glass container by subtracting the referencecurve from the measurement-ratio curve for such glass container anddividing the result by the reference curve.
 4. A method according toclaim 3, wherein the method further comprises: f. comparing the relativedifference curve of each hot glass container with a predeterminedtolerance curve; and g. generating an alarm signal if the relativedifference curve exceeds the tolerance curve in at least one point.
 5. Amethod according to claim 3, wherein the forming machine is operated bya control unit, and wherein the method further comprises the followingstep: h. sending the relative difference curve of each hot glasscontainer to the control unit to automatically control the formingprocess.
 6. A method according to claim 1, wherein the measurement unitis sensitive to radiation wavelengths of between 0.7 and 3.0 microns. 7.A system for monitoring a glass container forming process, wherein theforming process is accomplished by a forming machine which is controlledby a control unit and which contains multiple independent sections eachhaving at least one forming station at which glass containers areformed, comprising at least one measurement unit sensitive to theradiation emitted by the hot glass containers immediately after theforming machine, generating images of each hot glass container arrangedin a finite number of image lines, each image line having a finitenumber of pixels, and a processor unit to provide calculations,comparisons and communications with other units, characterized in thatthe processor unit is further programmed to carry out the followingsteps for each glass container measured from each forming station: a.determining a total radiation measurement for each glass container bysumming the digital values of all the pixels in all the image lines forsuch glass container; b. determining a line radiation measurement foreach image line for each glass container by summing the digital valuesof all the pixels in such image line for such glass container; and c.determining a measurement-ratio curve for each glass container bydividing the line radiation measurements for each image line of suchglass container by the total radiation measurement for such glasscontainer.
 8. A system according to claim 7, wherein the processor unitis further programmed to carry out the following step: d. determining areference curve by averaging the measurement-ratio curves over apredetermined number of the containers originating from all or from aselected number of forming stations.
 9. A system according to claim 8,wherein the processor unit is further programmed to carry out thefollowing steps: e. determining a relative difference curve for each hotglass container by subtracting the reference curve from themeasurement-ratio curve of each hot glass container and dividing theresult by the reference curve.
 10. A system according to claim 9,wherein the processor unit is further programmed to carry out thefollowing steps: f. comparing the relative difference curve of each hotglass container with a predetermined tolerance curve; and g. generatingan alarm signal if the relative difference curve exceeds the tolerancecurves in at least one point.
 11. A system according to claim 9, whereinthe relative difference curve of each hot glass container is sent to thecontrol unit to automatically control the forming process.
 12. A systemaccording claim 7, wherein the processor unit is further programmed tocarry out the following step: h. sending the relative difference curveof each hot glass container to the control unit to automatically controlthe forming process.
 13. A system according to claim 7, wherein themeasurement unit is sensitive to radiation wavelengths of between 0.7and 3.0 microns.
 14. A system according to claim 12, wherein themeasurement unit comprises: a Short Wave Infrared (SWIR) camera.
 15. Amethod of monitoring a glass container forming process using radiationemitted by hot glass containers formed in an I.S. machine, the methodcomprising: measuring radiation emitted by each hot glass containerimmediately after the glass container is formed and before it is cooled;determining, based on the measuring step, a line radiation measurementcurve as well as a total radiation measurement for each hot glasscontainer; and determining a measurement-ratio curve for each containerfrom each forming station by dividing the line radiation measurementcurve by the total radiation measurement.
 16. A method according toclaim 15, wherein the method further comprises: determining a referencemeasurement-ratio curve based upon the measurement-ratio curves for aplurality of containers;
 17. A method according to claim 16, wherein themethod further comprises: determining a relative difference curve foreach hot glass container by subtracting the reference measurement-ratiocurve from the measurement-ratio curve of each hot glass container anddividing the result by the reference measurement-ratio curve.
 18. Amethod according to claim 17, wherein the method further comprises:comparing the relative difference curve of each hot glass container witha predetermined tolerance curve.
 19. A method according to claim 18,wherein the method further comprises: generating an alarm signal if therelative difference curve exceeds the tolerance curve in at least onepoint.
 20. A method according to claim 17, wherein the method furthercomprises: using the relative difference curve of each hot glasscontainer to automatically control the forming process.
 21. A methodaccording to claim 15, wherein the measuring radiation step is sensitiveto radiation wavelengths of between 0.7 and 3.0 microns.
 22. A systemfor monitoring a glass container forming process using radiation emittedby hot glass containers formed in an I.S. machine, the systemcomprising: a measurement unit that measures radiation emitted by eachhot glass container immediately after the glass container is formed andbefore it is cooled; and a processor unit that determines, based on themeasuring step, a line radiation measurement curve as well as a totalradiation measurement for each hot glass container; wherein theprocessor unit also determines a measurement-ratio curve for eachcontainer from each forming station by dividing the line radiationmeasurement curve by the total radiation measurement.
 23. A systemaccording to claim 22, wherein the processor unit also determines areference measurement-ratio curve based upon the measurement-ratiocurves for a plurality of containers.
 24. A system according to claim23, wherein the processor unit also determines a relative differencecurve for each hot glass container by subtracting the referencemeasurement-ratio curve from the measurement-ratio curve of each hotglass container dividing the result by the reference measurement-ratiocurve.
 25. A system according to claim 24, wherein the processor unitalso compares the relative difference curve of each hot glass containerwith a predetermined tolerance curve.
 26. A system according to claim25, wherein the processor unit also generates an alarm signal if therelative difference curve exceeds the tolerance curve in at least onepoint.
 27. A system according to claim 24, wherein the relativedifference curve of each hot glass container is used to automaticallycontrol the forming process.
 28. A system according to claim 22, whereinthe measurement unit comprises: a Short Wave Infrared (SWIR) camera.